upgrpredgv

Description: An edge of a pseudograph always connects two vertices if the edge contains two sets. The two vertices/sets need not necessarily be different (loops are allowed). (Contributed by AV, 18-Nov-2021)

	Ref	Expression
Hypotheses	upgredg.v	$⊢ V = Vtx (G)$
	upgredg.e	$⊢ E = Edg (G)$
Assertion	upgrpredgv	$⊢ (G \in UPGraph \land (M \in U \land N \in W) \land \{M, N\} \in E) \to (M \in V \land N \in V)$

Proof

Step	Hyp	Ref	Expression
1		upgredg.v	$⊢ V = Vtx (G)$
2		upgredg.e	$⊢ E = Edg (G)$
3	1 2	upgredg	$⊢ (G \in UPGraph \land \{M, N\} \in E) \to \exists m \in V \exists n \in V \{M, N\} = \{m, n\}$
4	3	3adant2	$⊢ (G \in UPGraph \land (M \in U \land N \in W) \land \{M, N\} \in E) \to \exists m \in V \exists n \in V \{M, N\} = \{m, n\}$
5		preq12bg	$⊢ ((M \in U \land N \in W) \land (m \in V \land n \in V)) \to (\{M, N\} = \{m, n\} \leftrightarrow ((M = m \land N = n) \lor (M = n \land N = m)))$
6	5	3ad2antl2	$⊢ ((G \in UPGraph \land (M \in U \land N \in W) \land \{M, N\} \in E) \land (m \in V \land n \in V)) \to (\{M, N\} = \{m, n\} \leftrightarrow ((M = m \land N = n) \lor (M = n \land N = m)))$
7		eleq1	$⊢ m = M \to (m \in V \leftrightarrow M \in V)$
8	7	eqcoms	$⊢ M = m \to (m \in V \leftrightarrow M \in V)$
9	8	biimpd	$⊢ M = m \to (m \in V \to M \in V)$
10		eleq1	$⊢ n = N \to (n \in V \leftrightarrow N \in V)$
11	10	eqcoms	$⊢ N = n \to (n \in V \leftrightarrow N \in V)$
12	11	biimpd	$⊢ N = n \to (n \in V \to N \in V)$
13	9 12	im2anan9	$⊢ (M = m \land N = n) \to ((m \in V \land n \in V) \to (M \in V \land N \in V))$
14	13	com12	$⊢ (m \in V \land n \in V) \to ((M = m \land N = n) \to (M \in V \land N \in V))$
15		eleq1	$⊢ n = M \to (n \in V \leftrightarrow M \in V)$
16	15	eqcoms	$⊢ M = n \to (n \in V \leftrightarrow M \in V)$
17	16	biimpd	$⊢ M = n \to (n \in V \to M \in V)$
18		eleq1	$⊢ m = N \to (m \in V \leftrightarrow N \in V)$
19	18	eqcoms	$⊢ N = m \to (m \in V \leftrightarrow N \in V)$
20	19	biimpd	$⊢ N = m \to (m \in V \to N \in V)$
21	17 20	im2anan9	$⊢ (M = n \land N = m) \to ((n \in V \land m \in V) \to (M \in V \land N \in V))$
22	21	com12	$⊢ (n \in V \land m \in V) \to ((M = n \land N = m) \to (M \in V \land N \in V))$
23	22	ancoms	$⊢ (m \in V \land n \in V) \to ((M = n \land N = m) \to (M \in V \land N \in V))$
24	14 23	jaod	$⊢ (m \in V \land n \in V) \to (((M = m \land N = n) \lor (M = n \land N = m)) \to (M \in V \land N \in V))$
25	24	adantl	$⊢ ((G \in UPGraph \land (M \in U \land N \in W) \land \{M, N\} \in E) \land (m \in V \land n \in V)) \to (((M = m \land N = n) \lor (M = n \land N = m)) \to (M \in V \land N \in V))$
26	6 25	sylbid	$⊢ ((G \in UPGraph \land (M \in U \land N \in W) \land \{M, N\} \in E) \land (m \in V \land n \in V)) \to (\{M, N\} = \{m, n\} \to (M \in V \land N \in V))$
27	26	rexlimdvva	$⊢ (G \in UPGraph \land (M \in U \land N \in W) \land \{M, N\} \in E) \to (\exists m \in V \exists n \in V \{M, N\} = \{m, n\} \to (M \in V \land N \in V))$
28	4 27	mpd	$⊢ (G \in UPGraph \land (M \in U \land N \in W) \land \{M, N\} \in E) \to (M \in V \land N \in V)$

Metamath Proof Explorer

Theorem upgrpredgv

Proof